Method and system for addressing the problem of discovering relevant services and applications that are available over the internet or other communications network

ABSTRACT

A system and method is presented that extracts snippets form web pages according to specially designed logic. The extracted snippets might be made relevant to, i.e., indexed by, a location and time/day applicability. Such snippets may be thought of as apps or services that are defined only when a mobile terminal is in a pre-defined geographical area at a certain time and day (e.g., as defined by a calendar of events). Extracted snippets are stored and made searchable. Methods and a system are described to control the display of snippet search results. Snippets may be selected by user or by programmed logic and executed on the mobile terminal or in remote servers without the need to download the app or source code associated with the snippet.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. Ser. No. 15/139,718, filed Apr. 27, 2016, which is a continuation-in-part of U.S. patent application Ser. No. 15/076,779, filed Mar. 22, 2016, which is continuation of U.S. patent application Ser. No. 14/466,676, filed Aug. 22, 2014 entitled “METHOD AND SYSTEM FOR ADDRESSING THE PROBLEM OF DISCOVERING RELEVANT SERVICES AND APPLICATIONS THAT ARE AVAILABLE OVER THE INTERNET OR OTHER COMMUNICATIONS NETWORK”, which is a Non-Provisional of U.S. Provisional Application No. 61/868,707, filed Aug. 22, 2013, the disclosures of which are incorporated herein by reference in their entireties.

FIELD OF THE INVENTION

The present invention relates generally to displaying large number of web services so that consumers may be able to navigate to the relevant parts in less time with less effort.

BACKGROUND

The Internet/web has enormous amounts of content that is readily available to consumers. Websites contain large amounts of information or provide services that help consumers. Consumers may also download applications (“apps”) that provide specific services. Several search engines exist that assist consumers in finding websites and apps/services that are relevant to their needs. However, a basic assumption of such systems is that the consumer is assumed to have some idea of what they are seeking. Such a priori knowledge may not be available in certain situations. In other cases, despite having such a priori knowledge, a consumer may not have downloaded an app that is relevant to his current and immediate needs in a certain situation. Therefore, it is of commercial and consumer benefit to satisfy the informational and service needs of consumers who find themselves in unknown and unanticipated situations.

SUMMARY

A web page is the fundamental unit of discourse in the forthcoming disclosure. A website is a collection of one or more web pages accessible from a single address, or location, on the Internet by standard intermediation by a web server.

In accordance with one aspect of the invention a method is provided that de-constructs a web page into its constituent blocks, called “snippets,” and constructs one or more relationships between the various snippets.

In accordance with another aspect, the invention de-constructs a web page into one or more snippets based on recognizing visual boundaries and visual demarcations such as borders, copyright notices, column dividers, etc., or syntactical constructs that are pre-defined on the source code of the web page, and constructs one or more relationships between snippets from a single web page or from multiple web pages.

In accordance with another aspect, the invention de-constructs a web page into snippets by utilizing, in a collaborative fashion, web crawling systems such as Lucene, Scrapy, Nutch, etc., to analyze the web page.

A distinction is to be noted. There are many known examples wherein a new web page is constructed by analyzing a plurality of web pages. We are discussing a process wherein a single web page acts as a progenitor of a plurality of snippets, i.e., the former is a many to one relationship whereas the latter is a one to many relationship.

In accordance with another aspect the invention establishes a hierarchical relationship between the snippets extracted or derived from a web page, said relationship captures which snippets contain other snippets as sub-objects and which snippets are at the same, higher or lower hierarchical order.

In accordance with another aspect the invention utilizes specially designated, pre-determined syntactical constructs to demarcate snippets in the source code of web pages.

In accordance with another aspect the invention associates geographical locations and time/day of applicability to extracted snippets.

In accordance with another aspect the invention makes extracted snippets available to a snippet accumulation component by using a “push” method of transmission.

In accordance with another aspect the invention allows a searchable index of snippets to be built by allowing vendors and service or app providers to “push” content into a searchable index.

In accordance with another aspect the invention stores the derived snippets in a data store, maintaining its association with the original web page, i.e., an index is maintained that identifies which snippet is associated with which web page. Furthermore, associations between the contents of the snippet and its sub-components are maintained in the designated data structure.

In accordance with another aspect the invention utilizes technologies to scale the storage to a large number of snippets and web pages, e.g., by using multiple and redundant storage systems, servers, replication technologies, storage arrays, etc.

In accordance with another aspect the invention stores online trending information and associates said information with stored snippets.

In accordance with another aspect the invention stores usage of snippets indexed by their geographic location applicability and time/day of applicability.

In accordance with another aspect the invention utilizes machine-learning technology to assign a ranking function and control the display of search results on a mobile terminal.

In accordance with another aspect the invention utilizes usage statistics of snippets, geographical location applicability, time/day applicability, current online trending information as aspects or features in a collaborative filtering technology of a machine learning system.

In accordance with another aspect the invention requires that user mobile terminal reports its geographical location periodically to a snippet discovery component (SDC), said SDC constructing possible movement-related contexts for said consumer. Movement related contexts describe characteristics of the movements of consumers, e.g., if a consumer is stationary, moving at a certain rate, is lingering near another location, has repeatedly returned to a location, etc.

In accordance with another aspect the invention stores user movement contexts for later usage, said storing being indexed by snippets used by the consumer.

In accordance with another aspect the invention utilizes the stored movement contexts to train a machine learning function to predict what snippets are most relevant to a consumer in a given movement context.

In accordance with another aspect the invention allows a snippet's geographic area of applicability to be defined with respect to a well-known or historic landmark.

In accordance with another aspect the invention determines how a snippet is to be displayed, e.g., as a logo or rendered as a video clip, etc., by considering the contents of display constraints enunciated by information stored in the data structure holding the snippets.

In accordance with another aspect the invention determines what snippets can be displayed or prevented from being displayed in conjunction with other snippets based on constraints enunciated by the data structure holding the stored snippets.

In accordance with another aspect the invention constructs web pages to display snippets (hereinafter referred to as snippet pages) by utilizing style sheets, formatting information, templates, color charts, branding information and advertising content from the associated web page providers or from third party providers.

In accordance with another aspect the invention delivers one or more snippet pages to a consumer device a priori to the consumer device making a snippet search request.

In accordance with another aspect the invention moves snippet pages to server and storage sites, i.e., points of presence locations, that are proximate to the location of the consumer's terminal (e.g., a mobile terminal such as a smartphone. tablet, laptop, etc.)

In accordance with another aspect the invention causes the snippet pages to be delivered to the consumer terminal periodically, indexed by user location, snippet location of applicability, snippet time/day applicability, online trending context, snippet usage statistics at a certain geographic location, etc.

In accordance with another aspect the invention causes a consumer terminal to receive the snippet pages and one or more user selectable icons to be displayed on the requested web page. Furthermore, the display of the user selectable icon(s) may be contemporaneous with an audible alert message rendered on the consumer's terminal.

In accordance with another aspect the invention causes the snippet pages to be rendered on the consumer terminal in response to the consumer selecting the user selectable icon. Furthermore, said rendering may alternatively or additionally be triggered by specific audible sounds, verbal commands, or haptic gestures executed by the consumer.

In accordance with another aspect the invention renders the snippet pages as overlays on the associated web page being displayed on the consumer terminal.

In accordance with another aspect the invention renders the snippet pages in a third dimension with respect to the two-dimensional display of the associated web page.

In accordance with another aspect the invention renders the snippet pages within a holographic display with respect to the associated web page.

In accordance with another aspect the invention renders the snippet pages on a second display of the mobile terminal, i.e., the mobile terminal has two or more display screens.

In accordance with another aspect the invention renders the snippet pages on displays associated with the mobile terminal, e.g., displays that are proximate to the mobile terminal, or display devices where the same consumer has a currently authenticated session.

In accordance with another aspect the invention renders the snippet pages as a “star field” in which the snippets initially are displayed as small “dots” and as the user engages in a search for the relevant snippet(s), the star field zooms in gradually to show more detail of the snippets.

In accordance with another aspect the invention allows the use of trending information from external sources to be used to find relevant snippets and control the display and ranking function of snippet search results.

In accordance with another aspect the invention renders the snippet pages in a preferential order, one by one, e.g., a playlist of snippet pages. Furthermore, the method allows the consumer to control the preferential display of the snippet pages, to alter the rate of display, stop the display at a certain snippet page, terminate the display of the snippet pages, revert to a previously displayed snippet page, reverse the display order, etc., said control being exercised by audible or verbal commands or haptic gestures.

In accordance with another aspect the invention causes the current context to be selected by utilizing audible, verbal commands or haptic gestures. Furthermore, gestures may be defined to operate on the plane of the third dimension used to display a snippet page, e.g., intercept the plane of the third dimension.

In accordance with another aspect the invention causes consumer input to be accepted by a snippet page in the current context of the consumer device. In particular, the method allows a consumer to invoke a procedure, e.g., launch a command, delineated on the snippet page. Furthermore, said invocation may cause a new web page or new snippet page(s) to be fetched and/or displayed as a result of the invocation.

In accordance with another aspect the invention uses the software code or app associated with a snippet to be executed by a command issued by the consumer.

In accordance with another aspect the invention allows the consumer to bookmark a snippet page. Furthermore, it allows a consumer to re-load one or more previously bookmarked snippet pages.

In accordance with another aspect the invention executes the app or source code associated with a snippet in the user mobile terminal browser without downloading the app or source code.

In accordance with another aspect the invention executes the app or source code associated with a snippet in an execution environment distinct from the user mobile terminal, and displaying the results of the execution in a browser running on the user terminal, thus obviating the need to download the app associated with the snippet.

In accordance with another aspect the system and methods of the present invention provide the functionality and constitute a new kind of repository (e.g., an “app store”) in which apps do not need to be downloaded prior to their use. Rather, apps are discovered contextually as and when needed and discovered apps are executed in a safe and secure environment external to the mobile terminal and its memory space or within the memory of the mobile terminal. The user of such an app store is freed from anticipating the future need of an app and uses services and apps by discovering them contextually as and when needed.

In accordance with another aspect the invention provides system and methods to enable ICDs to be contextually discovered and utilized either through their web pages or via their discovery broadcasts. Additional information about a discovered ICD, e.g., its control API, may be obtained by recourse to a Directory Server. Information pertaining to ICDs that is received is packaged as snippets, stored and made searchable.

In accordance with another aspect of the invention a discovered ICD may be commanded to perform a service, said command being issued by a consumer by interacting with the snippet page corresponding to the discovered ICD, said snippet page being returned to the consumer as a result of a posited search request.

In accordance with another aspect of the invention systems and methods are provided that provide the functionalities and constitute a search engine for ICDs, sometimes also known in common parlance as the Internet of Things. In such an embodiment the system and methods provided allow the dynamic discovery of Internet resources, e.g., devices, and their capabilities such as control APIs, etc. Such resources are discovered as and when needed by consumers using their mobile terminals, such discovery being contextual by being related to the geographical location of the resource, the consumer terminal, the online context, the current time/day, etc. When discovered a consumer may initiate an interaction with said resource by issuing commands using a control API specific to the discovered resource. The computational processes and resources triggered by or launched by the user command may utilize the memory space and resources of the mobile terminal or utilize the memory and computational resources of external computing and storage elements (accessed online through a network connection).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows one example of a snippet extraction and discovery system constructed in accordance with the present invention.

FIG. 2 is a block diagram of one illustrative exemplary web page snippet extractor for implementing an embodiment of the invention.

FIG. 3 shows one example of the web page snippet exactor, the snippet accumulation component and the snippet storage component.

FIG. 4 is a flowchart illustrating one example of a secure communication protocol that may be employed between the web page extractor and the snippet accumulation component.

FIG. 5 shows one example of an internal data structure that may be used to store the snippets received by the snippet storage component.

FIG. 6 shows an illustrative physical environment associated with the snippet processing system.

FIG. 7 shows a tabular structure used by applications.

FIG. 8 illustrates the process of getting additional information about a physical object.

FIG. 9 illustrates an example of 4 locations (as determined by registration or location-reporting events) and the elapsed time between registration events.

DETAILED DESCRIPTION Introduction

App stores have been very popular with mobile consumers. Consumers routinely download hundreds of apps on to their mobile devices and use these apps during their daily lives. A central assumption in this area of technology is that a consumer has anticipated a need and downloaded a relevant app before he can use said app. In other words consumers must have a priori knowledge that they will need said app. Given that there exist hundreds of millions of apps it is not feasible to download all apps for every possible eventuality, even if we could predict all that may confront us in our daily lives. It is also true that we often find ourselves in unknown circumstances, new locales, and unfamiliar and unanticipated situations. It is then pertinent for a consumer to ask, is there an app suitable for the present situation?

In recourse a consumer who finds himself in an unfamiliar situation may engage in a web search by using a search engine. Hundreds of millions of web pages exist containing a wealth of information. Consider a consumer carrying a mobile terminal, e.g., a smartphone, tablet, laptop or other such portable communication device that is able to communicate over a fixed and/or wireless network such as the Internet or other wide area network. The consumer, upon finding himself in need of an unanticipated service, wishes to search for available services in his current location at the current time. For example, the consumer may be at Yankee Stadium on game day and wishes to find services that enable him to seek out the shortest line for buying game souvenirs. Present day search engines provide location-specific search mechanisms but these are not indexed by location synchronized with time and day, e.g., events defined by a calendar such as the Yankees game calendar for a given season.

It may be possible for a consumer to issue several search requests, each individually geared to getting a collection of responses that loosely pertain to his original search criteria. For example, the consumer may issue a request for services available in the general vicinity of Yankee Stadium. He may then proceed to issue requests for services available on game day. Then the consumer may find items that are common between the former and the latter group of answers and sort through them to find services that interest him or that may be relevant. A common feature of many mobile terminals is the limited size of their displays. It is generally infeasible on a small display terminal with limited abilities to save interim search results to perform the sort of iterative computation that is described above. It would be much more feasible for a consumer to simply issue a single search request “shortest line service here and now” that returns responses that are specific to the location and time associated with the service.

In other words, the commonly used term “user context” in search technology may be extended to denote the location of the mobile terminal, current time at the location of mobile terminal, the social networking context (what is relevant to the consumer at this time and place according to his social network), the web context (what web page content is relevant to the consumer at this time and location), and any terms provided by the consumer himself. The user context is then used to derive responses to a search request that is continuously (in a sense described later) issued to a system that responds, said responses being capable of being displayed either by consumer commands or by policy control, said policy dictated by consumer or derived from past behavior of consumer by said system.

To summarize, the present state of the art in web search and mobile app technology fails to teach how to respond effectively to search requests of mobile users who wish to ask, what services are available here and now? Or, Is the service XYZ available here and now? Or, what apps are relevant here and now? The term “effectively” identifies a solution that does not require the user to engage in iterative and detailed computations requiring the usage of saved interim search results, e.g., actions that are infeasible to be carried out on small mobile devices.

Overview

FIG. 1 shows one example of a snippet extraction and discovery system constructed in accordance with the present invention. A “snippet” is a portion of a web resource that most often, but not exclusively, identifies the resource, its address, main functionalities and use/purpose, mode of usage, etc. Examples of web resources include but are not limited to web pages, websites, Internet Connected Devices (ICDs), apps, web services, etc. Usually but not exclusively snippets pertain to services, apps or devices that are associated with a geographical location, called the geographic applicability of the snippet. Also, snippets are most often associated with services, apps or devices that are associated with a time and day event as in a calendar. These associations are called time/day applicability. In some cases a type of ICD often referred to as a “beacon” may serve to identify a location that in turn may be used to define the location of a service/app and, thus, become a part of a snippet that describes said app/service. The term “beacon” refers to small transmitting devices such as those manufactured by Qualcomm (called Gimbals), or defined by Apple (called iBeacons), and manufactured and identified by other companies. Beacons are physically installed at geographic locations where they trigger apps and/or the OS of smart phones and other mobile terminals that are proximate to an installed beacon and which have registered to receive beacon signals.

A snippet extractor 500 component extracts certain specific parts of web resources as dictated by special-purpose hardware and software logic. In some cases the snippet extractor 500 receives device information from web pages pertaining to ICDs that have been installed in various geographic locations, such devices being described by their corresponding web pages, websites or web directories, i.e., web resources. In other cases, smart phones, tablets, etc., (collectively referred to as mobile terminals) that are proximate to ICDs/beacons receive broadcast or transmitted information from said devices and relay it to the snippet extractor. The snippet extractor 500 may use known techniques taught in discovery protocols. The snippet extractor 500 converts received device information, consulting a Directory Server as needed (not shown in FIG. 1), into snippets. Thus, the mobile terminals may be utilized to “mine” geographical installed ICD/location information.

Information pertaining to a web resource may also be “pushed” by the authors/owners of said resource to the snippet extractor 500 or the snippet extractor 500 may seek and find web resources using its own internal logic. When using push to send information to the snippet extractors, said task may be simplified and aided by providing authoring tools, messaging tools, widgets etc. to facilitate the task of the authors.

The extracted snippets are “pushed” to a snippet accumulator component 1000 by the snippet extractor 500. The snippet extractor 500 accumulates said snippets and stores them in a specially designed snippet storage component 3000, which serves as a user searchable data structure. Thus, the data store is built up by receiving information sent by the snippet extractor 500. This data store contains snippets that describe apps, services and ICDs. The snippets may thus be logically viewed as pieces of information pertaining to services, apps and ICDs, said pieces being assembled into a structured format and stored in a searchable directory.

It is expected that the number of apps, services and ICDs will continue to grow and the size of the data structure 3000 will need to be extremely large. Moreover, updates to services, apps and ICD capabilities will need to be accommodated. Thus, the data store, i.e., the snippet storage component 3000, needs to be scalable, reliable and distributed. Several technologies are taught by prior art to achieve these goals such as the Hadoop Distributed File System, Cluster Computing, and Resilient Distributed Datasets, for example.

The snippet storage component 3000 is searchable by a snippet discovery component (SDC) 4000. Most often, but not exclusively, the SDC allows mobile consumers to use their terminals to pose search requests to the snippet storage component via the Internet or other communications network. A typical inquiry may have the intent “What services, apps or ICDs are available here and now”. Such inquiries may be posited by using a variety of input methods, including but not limited to keyword-based text searches, haptic gestures, clicking displayed icons, verbal commands, etc. In certain cases the SDC may work autonomously and pose inquiries under programmatic control, e.g., every few minutes, or displaying the latest results upon receiving an external trigger, or saving the results for a later time.

The snippet discovery component 4000 receives results from the snippet storage component and uses the display control component (DCC) 7000 to control the displaying of the results. The DCC 7000 dynamically coverts the received results into web pages referred to as snippet pages that are amenable to being displayed in conventional mobile web browsers. Because of the limited size of the display screens of many mobile terminals, the DCC may employ a variety of techniques and technologies to display the web pages. One such technique involves overlaying the snippet page onto a pre-existing web page that is being displayed on the screen of the mobile terminal. Another technique may be to display the snippet page as an object in the third dimension on a two-dimensional display. Another variant may be to display results using holographic techniques and technologies. The goal of such techniques is to display the snippet pages without erasing the previous content being presented on the screen. It is assumed that switching back and forth between screens of content may be cumbersome for mobile users. Alternatively, the snippet pages may be displayed on the mobile terminal screen for a few instants of time and then the original contents are displayed again, such an alternating display strategy being carried out a pre-determined number of times or until a command is received from the consumer.

In some embodiments snippet pages being displayed on the screen of a mobile terminal have all the functionalities of conventional web pages. Thus, they may be bookmarked, they may contain hyperlinks that can be clicked, they may contain commands that may be executed, etc. Again, a variety of techniques may be used to effectuate actions on the contents of the snippet pages, e.g., keyboard input, touch gestures, haptic commands, etc.

It is expected that the number of snippet pages containing the results of search requests may be very large. Mobile consumers typically find it cumbersome to peruse and consume information spread across several web pages on mobile terminals. In certain cases the snippet discovery component 4000 may consult a Response Ranking Component (RRC) 5000 to create a priority queue of the received answers. Such a priority queue may then be used to construct the snippet pages, said pages containing responses reflecting the ordering of the queue. The DCC 7000 may decide to, for example, only show the first few snippet pages, e.g., the first snippet page with the top ranked five (5) responses, etc.

The RRC 5000 may utilize various known techniques and technologies such as machine learning technology, for example, to rank order the snippets received as results to inquiries. In some embodiments the RRC has access to a machine learning component 6000 that uses various pieces of information in snippets as facets or features to train a system to discern the likes of a consumer at a given location and time/day. The learnt function is used to predict what snippets will be most useful to a consumer in a given situation (user context, online context, geographical and time/day applicability). In essence this amounts to asking what snippets were found to be most used in similar situations. These considerations result in curtailing the number of snippets needed to be included as results to an inquiry or to determine the rank ordering of the results. The main elements of this embodiment employ a “continuous” appeal to machine learning technology to predict what snippets (equivalently, what services, apps and ICDs) a consumer will like in a given “situation”. The term “continuous” refers to an ongoing periodic activity, the period being determined by computational constraints. The term “situation” refers to the geographical location and the time/day when the inquiry is posed, in addition to the online trending information and any other user information available to the system and methods of this invention. Some embodiments use all such information as facets and features in a machine learning system to make predictions of user likes.

As has been stated above, snippet pages, when displayed, may be designed to have full functionality as conventional web pages. And as has also been stated above, since snippets correspond to services, apps or ICDs, displayed snippet pages may accept user commands and provide services to consumers. A consumer may thus click an object or icon on a snippet page and cause a computation to be initiated or launched. Such computations may be executed, for example, in the memory of the mobile browser running on the user's mobile terminal. The logic corresponding to such an execution may be obtained by the snippet by recourse to the snippet storage component 3000, e.g., the computation may execute as a conventional applet.

Alternatively, the computation may execute as a conventional Servlet in a distinct execution environment available to the snippet discovery component 4000 and shown as module 2000 in FIG. 1. The snippet execution environment 2000 is a secure environment where computations may be executed on behalf of consumers interacting with displayed snippets. In such cases, as snippets are associated with apps, no download of an app is necessary. Thus, the snippet discovery component 4000 and the display control component 7000, in particular, and potentially other components shown in FIG. 1, may together constitute a new kind of repository (e.g., an “app store”) in which descriptions of apps are displayed on mobile terminals and users may interact with said descriptions by issuing commands. In such an app store apps need not be downloaded before their use. Rather apps are discovered contextually as and when needed, and discovered apps are executed to obtain results and derive services as and when needed. Thus the present invention proposes a fundamental departure from conventional app stores in which the downloading of apps is a fundamental precept.

As ICDs continue to be manufactured and installed it is expected that the number of such devices will continue to grow rapidly. In some embodiments the present invention caters to such devices by enabling the contextual discovery of such devices, either through their web pages or via their discovery broadcasts. Additional information about a discovered ICD may be obtained by recourse to a Directory Server (expected to be available as a part of the Internet infrastructure). All such information is received and packaged as a snippet, stored and is made searchable by the snippet discovery component 4000.

Snippet Extractor

FIG. 2 is a block diagram of one illustrative exemplary web page snippet extractor 200 for implementing an embodiment of the invention. Web page snippet extractor 200 may be employed, for example, in the system shown in system 1. Of course, the invention is not limited to the methods and techniques described below, which for illustrative purposes only are described in terms of a web page having a structured format that is based on a Hypertext Markup Language (HTML) layout pattern. The HTML layout pattern may be located within the source code of each web page. Of course, other types of structured formats may be employed instead of or in addition to HTML.

Web page snippet extractor 200 may be or can include a server such as a workstation running the Microsoft Windows, Mac OS, Unix, Linux or other operating system or platform. In some embodiments, web page snippet extractor 200 may comprise one or more servers. Also in some embodiments, web page snippet extractor 200 may be incorporated into or otherwise associated with a search engine, although in general the web page snippet extractor 200 and the search engine may be separate entities operated by different parties. Although not shown in FIG. 2, web page snippet extractor 200 includes a communication interface that allows it to be connected to any other device directly or over a communications network such as the Internet with fixed or wireless links.

Web page snippet extractor 200 includes a web page deconstruction component 202, a snippet extraction component 204 and snippet formatting component 206. In some embodiments, web page deconstruction component 202, snippet extraction component 204 and snippet formatting component 206 are integrated into one component. In other embodiments the individual components may act as standalone components and may be connected to each other through a fixed and/or wireless communication network. The web page deconstruction component 202 is a computer hardware or software component with logic configured to identify the various sections of a web page. In the context of a web page having an HTML layout pattern, the various sections that are identified may be HTML elements located between HTML tags or tag patterns.

In some embodiments the web page deconstruction component 202 can also be configured to rank the sections of a web page based on the importance of each section. The web page deconstruction component 202 may assign a ranking value to each section that identifies the importance of the section. The ranking value may be a number, text word or phrase, character, symbol, or any other identifier that may be used to convey the importance of the section. Typically, the most important sections will receive the higher-ranking values. In an embodiment, the web page deconstruction component 202 can determine the importance of a section based on keywords found within the text of the section. In such an embodiment, certain keywords (words or phrases) may be weighted more heavily than others such that their presence may denote the importance of the section. In another embodiment, the web page deconstruction component 202 can determine the importance of a section based on the type of tag or tag pattern that is associated with the section. For example, sections, which have tags or tag patterns exactly matching those being searched by the web page deconstruction component 202, may be deemed more important than tags or tag patterns that do not exactly match those being searched. Accordingly, sections with exact match tag patterns may be assigned a lower ranking value. Likewise, sections that have tag patterns with a simple starting and ending sequence of tags may be treated as less important than other types of tag patterns. In yet another embodiment, a user determines the importance of a section manually. In yet other embodiments, specialized snippet tags may be developed for use by web page authors for the purpose of having their web pages properly parsed into snippets.

In one particular embodiment the web page deconstruction component 202 operates on pre-determined and pre-defined set of HTML tags or other such syntactic constructs that are pre-agreed between the system of the present invention and the web page authoring process. In this embodiment the web page snippet extractor 200 component may be provided to web page authors as a System Development Kit (SDK), a widget to be included on said web page under authorship, or as a software library to be used in web page construction. The snippet extractor locates said tags and selects the multimedia or other object (e.g., text, graphics, video clip, audio clip, source code, hyperlink to source code, etc.) within the syntactic boundaries of the tags. The selected object is then identified as a primary section of the web page. The web page deconstruction component 202 may identify one or more than one such primary sections of a web page.

In an embodiment a web page author adds location, time, calendar and other relevant details concerning the web page into the pre-determined HTML tags or agreed-upon syntactic constructs so that the stated information may be picked up by the web page deconstruction component 202 as a primary section.

The snippet extraction component 204 is a computer hardware and/or software component with logic configured to extract text, images and/or other information from the sections identified by the web page deconstruction component 202. The information is extracted for use as a snippet to be included in a searchable index (described later). In an embodiment, the snippet extraction component 204 determines which portion of each section to extract based on a ranking value of the portions and the relevance of the portion to the search query. For example, the snippet extraction component 204 may first examine the ranking values of each section provided by the snippet deconstruction component 202 to determine which sections of the web page are most important. The snippet extraction component 204 may then compute a relevance value by comparing, for instance, the keywords of the search query to the text of the different portions of each section to determine which portions are most relevant to the search query. In an embodiment, the relevance value may be based on whether the keywords of the search query match any portions of the text of a section. The snippet extraction component 204 can be configured to select a desirable portion of each section that has the highest-ranking value and relevance value with respect to the search query. Once the desirable portion of each section is selected, the snippet extraction component 204 can extract that portion as a snippet to be associated with that section of the web page.

In another embodiment the snippet extraction component 204 locates a primary section of the web page previously identified by the web page deconstruction component 202 and identifies said primary section as a primary snippet for said web page. If said page has more than one primary section, the snippet extraction component 204 identifies each such primary section as a primary snippet of said web page.

The snippet formatting component 206 is a computer hardware and/or software component with logic configured to generate, construct or otherwise provide snippets that may be accumulated into a searchable index (detailed later) using the snippets obtained by the snippet extraction component 202. The manner in which the snippets are formatted may be based on a number of factors, including, for instance, the relevance value of each snippet, the nature (e.g., size) of the display available to the end-user's terminal, etc. In an embodiment the snippet formatting component 206 uses the primary snippets identified by the snippet extraction component, formats them in accordance with a pre-determined set of formatting rules and makes said snippets available to the searchable index. For example, a primary snippet may be formatted as a 2048-byte message and transmitted via fixed and/or wireless links to the snippet accumulator component 1000 of FIG. 1.

It should be noted that in the example presented above, a snippet was assumed to be a subsection of an HTML element (i.e., a section between HTML tags or tag patterns). However, in some embodiments a snippet may be commensurate with the entirety of an individual HTML element. That is, each section identified by the web page deconstruction component 202 may constitute a single snippet. In such a case the web page deconstruction component 202, in effect, also performs the functionality of the snippet extraction component 202.

For instance, an individual web site (having multiple web pages) may be deconstructed into snippets. Likewise, an individual domain (having multiple web sites) may be deconstructed into its constituent snippets. Moreover, in some cases two or more sites belonging to different domains but having an association with one another (e.g., a business relationship) may be deconstructed into its constituent snippets.

While the present invention has been described in terms of an arrangement for deconstructing an individual web page into its constituent snippets, more generally the arrangement may be employed to deconstruct other entities into their constituent snippets. For example, in the case of deconstructing an individual domain such as the domain abc dot com, the arrangement may extract one or more snippets from abc.xyz dot com and one or more other snippets from abc.123 dot com. As a concrete example, snippets from two web sites selling two related products, such as a car and a watch (e.g., Bentley and Breitling) may be extracted and presented as a single snippet or two related snippets (said relationship explained later).

Snippet Accumulation Component

FIG. 3 shows one example of the web page snippet exactor 200, the snippet accumulation component 300 and the snippet storage component 400. As previously mentioned, in some embodiments of the present invention snippets may be accumulated into a searchable index (e.g., snippet storage component 3000 in FIG. 1). The Web Page Extractor 200 in FIG. 2 takes one or more snippets as formatted by the snippet formatting component 206 and initiates a transmission to the Snippet Accumulation Component 300 in FIG. 3. In some embodiments it may be desirable to implement this transmission in a secure manner since the web page extractor 200 and the snippet accumulation component 300 may be operated by different entities. One example of such a protocol that may be employed is illustrated with reference to the flowchart of FIG. 4.

In step 1 of FIG. 4 the Web Page Extractor takes a snippet constructed by its Snippet formatting component (described above) and sends a message to the snippet accumulator component indicating that it wishes to send it a snippet.

In step 2 the Snippet Accumulation Component responds to said request with a unique security token or the like.

In step 3 the Web Page Extractor receives said unique tag and uses it to authenticate future messages.

In particular it uses (step 4) the unique tag to send the extracted snippet to the snippet accumulator component.

In step 5 the snippet is received and authenticated by the Snippet Accumulation Component.

In step 6 the received snippet is stored for later use in snippet storage component 400 (FIG. 3).

The above description uses a simplified example to delineate an illustrative protocol followed in sending, receiving and storing snippets resulting in the construction of a data store of snippets. In some cases conventional negotiation and handshake protocols may be employed. For example, the unique token may be generated and transmitted in a secure manner so as to avoid spurious requests. Of course, it is apparent that information other than a unique token may also be used in the protocol. For example, various attributes may be used to “signal” the type of content and formatting of the snippet, the kind of device recommended for display or execution of the snippet, etc. The communication between the Web Page snippet extractor 200, the Snippet Accumulation Component 300 and the snippet storage component 400 shown in FIG. 3 may occur over fixed and/or wireless links (not shown in FIG. 3) or these components may communicate over the Internet (not shown).

By way of example of prior art, SIP (Session Initiation Protocol) and SDP (Session Description Protocol) protocols may be employed, which describe extensive facilities for describing sessions, capabilities and negotiations between computing entities.

Snippet Storage Component

With continuing reference to the example in FIG. 3, the snippet storage component 400 receives snippets from the Snippet Accumulation Component 300 using a pre-determined protocol internal to the snippet storage component 400 and Snippet Accumulation Component 300. In this example the format of the received snippet is also pre-determined, pre-specified and known to both the snippet storage component 400 and the Snippet Accumulation Component 300. (The Snippet Accumulation Component described above may optionally re-format a received snippet according to its internal formatting rules.)

The snippet storage component 400 uses an internal data structure to store the received snippets. FIG. 5 shows an exemplary illustration of said data structure. The actual implementation of the data structure may vary according to the requirements of the invention.

FIG. 5 delineates the storage data structure as a table of rows and columns. Each row of the table corresponds to a stored snippet with a unique associated identifier and the columns contain various sub-components of the snippet. Only a few possible sub-components of the snippets are shown for pedagogical reasons. Some of the possible sub-components are described below.

The column “Cal” indicates a calendar entry that shows the dates and times of applicability of the snippet, i.e., when is the snippet capable of being executed.

The column “Loc” indicates the geographical location where the said snippet can be executed, i.e., each snippet is assumed to be localized to a given geographical region of a pre-determined size such as, by way of example, a circular region centered around a given location with radius 300 ft. The geographical points that define a region might be given by latitude and longitude, GPS coordinates, proximity to a well-known landmark (e.g., Yankee Stadium), etc.

The columns “Dev” and “Browser” refer to the recommended device and Internet Browser upon which said snippet might be executed.

The column “Link” denotes the hyperlink to the website from whence the snippet was extracted, i.e., received.

The column “Code” refers to another hyperlink to the location where the source code (if any) associated with said snippet is stored. It is envisaged by the present invention that the source code may be located in a location that is external or internal to the system comprising the present invention.

The column “Display” refers to any display-related constraints imposed by said snippet. For example, the snippet may specify that for terminals with small display sizes only the “logo” of the snippet may be displayed. Alternatively, in bandwidth-rich environments, e.g., if there is a WiFi connection available to the user terminal, the constraints may specify that a video clip may be rendered on the user terminal.

The column “Exec” refers to constraints on execution of the source code associated with the snippet. For example, authentication requirements or security concerns, etc., may be stated under this heading.

The column “Owner” refers to the information regarding ownership of snippet or contact information.

The column “Acc” refers to an accounting, billing and usage information repository.

The column “Rel” refers to other snippets that are related to said snippet and the nature of the relationship. The terms “related” and “relationship” are described in detail later.

As stated above the present invention envisages many more attributes, i.e., columns, as comprising the above data structure and only a few have been listed herein for exemplary purposes. Several examples of such attributes will be presented later.

In some cases the number of snippets that need to be stored may be extremely large (e.g., in the billions). Therefore, in some embodiments a distributed storage mechanism may be employed to hold all the data associated with the storing of snippets. Examples of such storage systems are the HDFS (Hadoop Distributed File System), possibly with RDD (Resilient Distributed Datasets) assistance implemented on large-scale cluster computing systems.

Relationship Between Snippets

As noted above, snippets from the same web page or domain, or from the same enterprise, or from different web pages might be inter-related. An example of such a relationship is provided by two snippets that may be “displayed” together, e.g., a wristwatch such as manufactured by Breitling and a Bentley automobile, i.e., the wristwatch in said case is associated with the automobile via branding by the two respective companies. As an alternative consider the snippet for Coca-Cola and Pepsi that may have a mutually exclusive display constraint.

The relationship between snippets is not limited to the display of snippets only; it may impact other behaviors associated with snippets. For example, two snippets may be related by mutually exclusive execution, e.g., two offers for a product may not be executed by the same consumer within a certain time limit, etc.

In some embodiments the present invention may capture snippet inter-relationships during the snippet extraction and identification phases (described earlier) and represent them in a special column in the snippet storage component 400. For example, the prime section identified by the snippet extraction component may contain information about such relationships as specified by the web page authors.

Snippet Discovery Component

The snippet discovery component (SDC) 4000 shown in FIG. 1 allows consumers to pose search requests against the data in the snippet storage component 3000. Thus, a search request such as “What services/apps are available here and now” may be responded to by searching the snippet storage component 3000 for all snippets matching the “here and now” specification, i.e., data, time and location constraints. It should be noted that while the search request above has been stated in English, this is merely for descriptive purposes. The present invention does not preclude the use of natural spoken language as an input mechanism, gesture-based inputs on touch sensitive surfaces, or “search box” type keyboard input systems or any other suitable input mechanisms. All of the above and other input methods may be used to specify consumer requests and one such mechanism is described later.

Furthermore, allowing the consumer to state additional information as a part of the request may increase the power of the search requests, e.g., “What services related to waiting lines are available here?” Or more succinctly as “waiting line services?”

While the present invention emphasizes the location and time of snippet based services and apps as a key point, it does not preclude the possibility that certain services may be defined via snippets that carry no location or calendar restrictions, i.e., such services or apps work everywhere and at all dates and times. For example, a Bank of America app may be defined as such a time and location-independent snippet. One method of stating such time and location-independent constraints is to declare a “don't care” value for the “Loc” and “Cal” columns in the snippet storage component data structure.

Many recent advances in Internet computing teach the extraction of trends from dynamic websites such as social networking sites, e.g., Facebook, and messaging sites such as Twitter and Instagram, etc. Such trends may be captured in the snippet storage component 3000 as well. In particular, in an embodiment when a consumer requests a search for a snippet, the resultant snippet(s) are remembered and the current trends are recorded when the search request was made. For example, assume that at certain time and location the Twitter trend comprises the hashtag #cold and that a consumer issues a search request to the snippet storage component 3000, resulting in snippet367 being returned as the response to the consumer request. The snippet storage component then stores the current trend #cold as a column attribute, e.g., “Trend”, with snippet367. Thus, the trend #cold is associated with snippet367. In a later section the invention discusses the embodiment of “ranking” responses to consumer search requests based on correlating trending information.

As another example of a special-purpose column attribute that may be introduced into the snippet storage component 3000 consider a new attribute “Used” defined for, say, snippet367, that refers to a list of snippet identifiers that are most often used at said “Loc”. In other words it is a list ordered by usage of snippets at the given location. For example, the value of the column attribute “Used” for row corresponding to snippet367 may be the list [{snippet322, 50}, snippet245, 45}, . . . ] signifying that snippet245 was executed 50 times at said location, snippet 322 was executed 45 times at said location, etc.

Response Ranking Component

As discussed above, the present invention assumes that the number of snippets in the snippet storage component 3000 may be very large and, therefore, the possibility exists that the responses to consumer requests might be overwhelmingly large to “consume”, particularly by mobile consumers with small display screens and those that are rushed for time.

In some embodiments we propose two different methods may be used as ranking functions, i.e., to sort the responses so that the most relevant are displayed first. The first method relates to the “Trend” column attribute described above. The second method relates to the “Used” attribute described above.

In both methods machine-learning technology may be used to derive strong correlations between snippets that are most frequently used by consumers in a given location and under given online trends. Known machine-learning technology shows how to take (large) data sets comprising user likes, dislikes, usage, etc., to predict what a known user would like, dislike, or use. For instance, many Internet websites use machine-learning technology to predict movies that a consumer might like, music that a consumer might enjoy, or a product that a consumer might purchase.

In the present invention machine-learning technology may be used as a ranking function, particularly using the attributes of past usage, current online trends, geographic location and calendar information where service or app is defined. Thus, the display function associated with a search request is correlated with certain attributes of the app or service and used to predict the likely app or services that are most relevant to a given consumer.

In some embodiments the present invention runs at a pre-defined and periodic rate for a consumer (or for all consumers), thus, “constantly” searching the current location of the consumer as said consumer moves in his daily routine. At periodic moments the services or apps available to the user are pre-computed and made ready for the consumer, i.e., the computation occurs in the background. If and when the consumer desires or if a pre-determined trigger is “sensed” by the mobile terminal then the pre-computed results might be made available to said consumer. Such computational processes that run periodically in the background may be implemented as a part of the OS of the mobile terminal, e.g., by modifying the launcher in the case of the Android OS, or by defining an app that is native to the mobile terminal OS.

User Movement Context

Currently available apps/services sometimes use user location data to provide location-specific information. Techniques for generating and receiving user locations from a mobile terminal are well-known. The present invention may use user location data to calculate and utilize user movements from user location data, said location data being generated by conventional means utilizing GPS or triangulation methods and technologies or by utilizing beacon registration messages, for example. (Because the beacons are installed at known specific geographic locations, when a mobile terminal is proximate to such a beacon and an app on said terminal is triggered, the app may communicate the triggered information to a server which may in turn determine the geographic location of the beacon and hence the mobile terminal itself.)

A user carrying a mobile terminal moving about a geographical location where beacons have been installed thus may said to be generating a series of registration and de-registration events on said beacons. (Equivalently, one may assume that the mobile terminal periodically transmits or makes available its location.).

Using the elapsed time and location data as indicated in FIG. 9, we may calculate many properties of the user's movements. For example, we may calculate how long a user spent between two consecutive locations. Moreover, if the spatial separation between said two locations is “small” compared to a reasonable transit time one may assume that the user stopped or “lingered” between the two locations. We may also calculate “return” trips wherein the user returns to a previously “visited” location. Other examples of user movement calculations include “repeat visits”, “approaching a location”, “exited a location X time units ago”, “returned to a location within X time units”, etc. Such user movement calculations may be called user movement context.

The user movement context may be utilized to infer user state, as for example in marketing situations, a user that is calculated to be “lingering” in close proximity to a retail item may be inferred to be interested in said retail item. Or if a user “returns” to the location of a certain retail item more times than a stated or calculated threshold may be assumed to be interested in said retail item. Similarly, a user that returns to the same location a number of times within a calculated number of time units may be assumed to be in need of geographical directions or assistance. Thus, there may exist a correlation between user movement context and user state. In other words the movements of a user may indicate his behavior in the physical world that in turn may indicate user intent or need.

In an embodiment of the present invention the user movement context of a user (as gleaned from registration/de-registration events or location reporting by his mobile terminal) is utilized to infer possible user intent and to utilize such information to influence said user intent, e.g., influence a user's purchase decisions. Said influence may be effectuated, for example, by transmitting or causing to be transmitted to the user, specific recommendations or advice as a function of his calculated user movement context.

In this context it is important to observe the recent use of Planogram protocols along with the use of beacons (mentioned earlier). Such protocols describe the layout, location and inventory of retail establishments. By way of example Table 1 below shows a fragment of such a protocol that describes a store that sells music. The first column gives the serial number of the installed beacon and its location coordinates are shown in columns 3 and 4. The second column gives the genre of the music stored at the beacon's location. The 5^(th) column gives the locations where users may be situated, i.e., these locations may be considered to be proximate to the beacon, ideally based on the signal strength of the beacon. (The latter locations can be determined by calculations involving the signal strength of the beacons as taught by prior art.)

Thus, if a user is situated at a certain location in the example retail establishment above the retail items contiguous or proximate to his location can be determined from the Planogram description. It may thus be ascertained, for example, that a user is situated proximate to the “dance and electronica” section. More precisely, the beacon messages received by the user's mobile terminal and conveyed to a server that causes a registration message to be generated. Analysis of such registration messages and the time of their receipt reveals user movement from which a context is calculated that gives various states of the user movement, e.g., a user is lingering, etc. Such user movement context may then be merged with Planogram information to determine that said user, by way of example, is lingering proximate to “dance and electronica” section.

TABLE 1 b00000100 classical 435 290 (505, 370) (488, 462) (499, 372) (514, 203) b00000101 classic pop and 656 290 (527, 200) rock (727, 188) (727, 384) (587, 377) b00000102 dance and 859 290 (924, 207) electronica (795, 380) (922, 374) (922, 292) b00000103 folk 1092 290 (1019, 377)  (1092, 449)  (1024, 367)  (1024, 213)  (1089, 99)  b00000104 hip-hop 435 673 (505, 574) (356, 587) (510, 751) (364, 574)

The present invention in some embodiments is able to:

(1) Allow marketers to define several different kinds of user movements, e.g., linger, repeat visits, return visits, stationary users, rapidly moving users, etc;

(2) Store the user movement contexts in a table along with (retail and other) items that are proximate to where the user movement context occurred, possibly from a Planogram-style description protocol;

(3) Store the user's purchase decision and the snippet(s) he utilizes or chooses;

(4) Use the above data to calculate a correlation between the user movement context and the eventual purchase decision and snippet usage of the user;

(5) Use the correlation information from above to predict, given a certain user movement context at a certain geographic location, what the user is likely to purchase and what snippet the user is likely to need or want or choose in a given user movement context.

The invention allows the system to recall what snippets were used most often given a user movement context. This information may be used to display the most likely, predicted snippet, i.e., it may be used by the Response Ranking Function to rank order the responses to a search request.

Furthermore, the invention may allow use of the user movement context not only for retail establishments and retail purchase decisions but also in general for all kinds of purchase decisions involving products and/or services, e.g., travel or hospitality situations, or even general decisions such as inferring user intent, e.g., “user is in a hurry”, “user is taking a walk”, etc.

Display Control Component

Once a search request has been issued and the resulting group of snippets assembled as a response to the search request, it is the task of the Display Control Component (DCC) 7000 (FIG. 1) to arrange for the display of said results. It is envisaged that the DCC may utilize style pages, formatting tools, etc., to format the results as web pages, referred to as snippet pages that are capable of being displayed on a user terminal, e.g., by using an available Internet Browser.

Several display strategies are possible in addition to displaying search results as snippet pages. For example, the user terminal may have two displays and the snippet pages may be displayed on the second display. Alternatively, the snippet pages may be displayed as an overlay to the existing information being displayed on the user terminal display, e.g., in a third dimension, or as an overlay with a different color scheme, etc. It is anticipated that the snippet pages will need to be displayed fairly often, e.g., as the user moves around visiting various geographical areas and new apps and services will become continuously relevant to his needs. Thus, display strategies that do not “erase” or “obscure” what content may already be present on the display screen will be particularly effective. For example, the snippet pages may be displayed in a sequence alternating with the original contents of the screen.

The DCC may also allow user commands to determine what is displayed and to control items that are being displayed, Again, several different modes of user commands may be used, e.g., haptic gesture commands, verbal commands, etc. may be employed to control the display of snippet pages.

The user may desire to select a snippet that is being displayed and cause it to be executed. Again, the user using a variety of gesture-based inputs, verbal commands, or gestures on touch sensitive screens may control the selection of a snippet and its subsequent execution.

Snippet Execution Component

Once a group of snippets are displayed to a consumer, said consumer may select a link or otherwise execute a command available in one or more displayed snippets, thereby causing an externally defined object to be executed. One possible execution strategy would be to have the selected snippet be associated in the snippet storage component with the location of a corresponding app that might be then downloaded to the consumer terminal whence it might be executed.

In another embodiment the present invention employs a distinct component, the Snippet Execution Component 2000 (FIG. 1), where apps associated with snippets as identified by the snippet storage component 3000 are stored and proceed to execute, i.e., it is a controlled execution environment that uses the consumer's mobile terminal as a display device. More specifically, it is assumed that the mobile terminal is equipped with an Internet Browser and said app runs as a servlet in the execution environment with its results displayed via HTML5 browser renderings. In such implementations the column attribute “Acc” of the snippet storage component may be used to keep track of accounting and billing statistics.

In another embodiment the source code or the app associated with a snippet (as indicated by the snippet storage component) may be allowed to execute in a remote server, e.g., owned by the enterprise that owns the snippet and the results of the execution are displayed in the browser of the consumer mobile terminal. One method of implementing such a mechanism is to use remote procedure invocation technology.

In another embodiment the source code or the app associated with a snippet (as indicated by the snippet storage component) may be allowed to execute as an applet in the memory space of the browser running on the consumer's mobile terminal.

Performance and Other Considerations

As described above the present embodiment allows the calculation of correlations between user movement contexts and snippet usage. Using this information the system of the present invention may predict what snippets are most likely to be needed by a user in a given user movement context. This information may be used by the system to deliver a selected and chosen number of snippets to a user's mobile terminal even before the user issues a search request. Such delivered snippets are stored in the user mobile terminal's memory and provided as responses to the user if and when a user request is made. Thus, the system anticipates the search requests of the user and improves its performance by using such anticipation-based methods. This relates to “caching” strategies. The present invention provides the innovation of using the user movement context to provide hints of what information is to be cached at the mobile terminal or at Points-of-Presence (POPs) locations so that responses may be delivered to the user efficiently and quickly. The term “efficiently” not only refers to the improved efficiency of the search mechanism as far as the user is concerned (improved response time as experienced by the user) but also concerns the important function of efficient usage of network resources. In wireless networks in particular such pre-fetching of potential answers and caching them either in user mobile terminals or at POPs can significantly improve the utilization of (wireless) network resources.

Co-Existence with Traditional App Stores

As described above the present embodiment specifies systems and methods that allow the construction of a repository analogous to an app store in which the operability and discovery of apps is confined and constrained to specific locations, times, days and dates. Moreover, a user need not download said apps to a mobile terminal prior to their usage.

However, the aforementioned embodiment does not preclude a user from using conventional apps and app stores. A user may download apps he currently likes, store them on his mobile terminal and use them in a conventional manner. At the same time a user may also use the systems and methods of the present invention to use the apps and services described herein.

In particular, the invention envisages a modus operandi in which the user downloads conventional apps and uses them conventionally. Furthermore, a protected environment is provided for the kinds of apps described by the current embodiment. The protected environment may provide security, accounting and performance guarantees. Indeed enterprises may use the systems and methods of the current embodiment to create “walled gardens” providing their users with services that are specific to their locations, time and date, etc. As has been described above, apps and services may also be defined using the present embodiment that are operable and discoverable everywhere, i.e., they have no location, time, or day constraints. Thus, the present invention provides a co-existence mechanism between the conventional app stores and the app stores enunciated by the present embodiment. Moreover, enterprises may define a collection of services and apps utilizing the system and methods of the present invention, each such collection becoming a distinct, firewalled and protected app store. One method of defining such a collection would be to use the relationship function between snippets described earlier (cf. Snippet storage component and Relationship between snippets sections above). For example, all snippets related to XYZ Corp are treated as inter-related and belonging to one distinct app store.

Many users who utilize their mobile terminals for both personal and business or job related services and apps end up having to purchase and use two separate and distinct terminals. The present invention provides systems and methods for a user to use only a single mobile terminal and yet keep his apps and services in distinct app stores that are protected, private, separately accounted and billed, and firewalled.

Additional Embodiments

As described above, snippets are stored in a snippet index with components that are referred to as attributes (see FIG. 5). Some of these attributes serve as applicability constraints that are used to determine their relevance to a query. The applicability constraints may include, but are not limited to, location, time and date. When a mobile device at a certain location issues a search request, the context (e.g., location, time and date) of the mobile device is used to query the snippet index and snippets having attributes that match the context are taken to be relevant to the search request. The user is presented with the relevant snippets, which may then select one or more snippets for execution.

A snippet may be executed on the user's mobile device. Alternatively, one or more network-based servers may be chosen to comprise an execution environment in which the snippet is executed. In the latter case, the results of the execution may be directed to one or more display devices (including the mobile device).

As previously mentioned, the snippets stored in the snippet index (FIG. 5) originate from web resources such as ICDs, applications, web services, resources tied to block chain environments, etc.

In one embodiment, the context of a mobile device may be extended to include specified locations where the mobile device is anticipated to be a specified date and time in the future, e.g., the context of the mobile device may be specified as New York City, July 4, 2 pm, even though the mobile device currently may be located elsewhere at an earlier date and time. If a search request is issued by the mobile device with the assumed (hypothetical) location, date and time, the snippet index may be searched to find relevant snippets and the relevant snippets may be returned as a result of the search request. Herein, the relevancy of snippets may be determined according to a future (e.g., hypothetical) context (location, date and time) of the mobile device.

As a practical example of the utility of conducting a search using a future context, consider a user who plans to travel to New York City at a future date such as July 4 and who wishes to determine what services may be available at that location on that date at 2 pm. The user may wish to make a reservation for certain services, etc.

As another example consider an enterprise that wishes to launch a marketing promotion at an event, say at a certain NY Yankees ballgame. Users may wish to browse such promotions in advance so that they may use the promotions while at the ball game. However, the promotion may offer its services only while the users are present at the ballgame.

The present invention calls for snippets to be extracted or received from web resources; websites, apps, web pages being exemplary web resources. In general, two types of methods may be used to extract snippets from the web resources. In one method, software programs, sometimes referred to as web crawlers, parse the web resources to extract attribute information and return extracted information back to the snippet system. This method is also sometimes referred to as a “pull” method. To facilitate the extraction of the attributes, special tags may be provided in the web resource which demarcate specific pieces of information and data. In the second method, the web resource may be designed using a pre-determined format to create one or more snippets and “push” the snippet(s) to the snippet system.

Thus, a mobile device issues a query containing the context of the mobile device. The snippet system responds with snippets that are relevant to the query. The method for determining the relevance of a snippet for a query from the context of a given mobile device may be described as follows.

-   -   1. An application running on mobile device “M” uses the internal         systems of “M” to sense its context (e.g., location, date,         time), encapsulates the context into a query, and sends the         query to the snippet system.     -   2. The snippet system receives the incoming query.     -   3. The snippet system retrieves those snippets from the snippet         index whose applicability constraint attributes “match” the         context of the incoming query.

FIG. 6 illustrates the above procedure. A physical environment 100 contains a mobile device 200. An app is running on mobile device 200 and senses the location, time and date of the mobile device as “L”, T”, and “D” respectively. Snippet index 300 contains a multitude of snippets of which S1, S2 and S3 have applicability constraint attributes that match “L”, “T” and “D”, i.e., the snippets are relevant. Therefore, the relevant snippets are presented by the application “app” to the user by, for example, displaying them on his mobile device. The user then may make a selection, say S1, and the selection may, if appropriate, result in the selected snippet being executed in the Execution Environment 400. The result of the execution of the snippets may be sent to the “app” that may then decide to display the results.

It is important to note here that, as described, a query is a term used to describe the action of interrogating a representation of the snippet index. (If we think of a database as a representation of stored data then a query would be a form of interrogating the stored representation.) Thus, the terms “query” and “context” are sometimes used herein interchangeably. However, to be clear, an application running on a mobile device may construct (or may have access to) the context of the mobile device. The application may then encapsulate the context into the form of a query that has a format that is consistent with the interfaces of the snippet system. That is, the context is converted into a query so that the snippet system may be interrogated.

Extending the Context of Mobile Devices

We observe that the web is replete with content of many types, any and all of which may be associated with snippets. Recently, Virtual and Augmented Reality (VR/AR) objects have begun being added to web resources. That is, snippets may reference content such that upon execution of the snippets, a user may be able to display and manipulate VR/AR content, as well as other content.

Thus, when a mobile device issues a query with a given context and relevant snippets are returned by the snippet system in response, we wish that execution of the snippets leads to the snippets having access to and manipulating specific pieces of web content.

However, as previously mentioned, in order to find relevant snippets, the snippet system needs applicability criteria. That is, the snippets need attributes that can serve as applicability constraints that define when a snippet is applicable to one or more web content. In the above examples calendar and geographic attributes (location, date and time) have been described as applicability constraints.

In order to achieve the above stated aim, we extend the notions of the “context” and a query of a mobile device as follows.

We extend the context of a mobile device to have attributes, in addition to the above stated location, date and time attributes. In particular, in one embodiment, one or more attributes defining the state of a mobile device may be utilized. Some particular examples of state attributes are unique identifiers for a characteristic of the mobile device such as the mobile device type (e.g., model number), the operating system running on the mobile device and one or mores “apps” running on the mobile device.

We further extend the concept of a query transmitted from a mobile device to the snippet system by including one or more event attributes in the query. These event attributes may be used in addition to, or instead of, the above-described state, calendar and geographic attributes.

One kind of event attribute concerns actions that are performed by a mobile device. For example, an app running on the mobile device may scan or otherwise acquire an image or video of a physical object. Thus, “event-type=“scan” may be an example of such an event attribute. As another example of an action, the mobile device, or an app running on the mobile device, may make a measurement using a sensor incorporated in or associated with the mobile device. Illustrative measurements include, without limitation, obtaining an image or video, measuring one or more health related parameters of a user of the mobile device, measuring motion of the mobile device and measuring ambient temperature.

Other exemplary event attributes may arise from the action of making a measurement. For instance, Event Content attributes arising from the act of making a measurement may correspond to values obtained from sensors (e.g., accelerometer, altimeter, thermometer, etc.) within or associated with a device and from proximate devices (e.g., heart rate monitor, blood pressure monitor, pedometer, etc.), where proximate devices may be, in certain embodiments, connected to a user's mobile device via wireless or wired network connections and may be in close proximity to the mobile device.

In some embodiments apps may use software logic to analyze the content arising from an event. For example, when an event-type=“scan” happens, an app may use internal software logic to analyze the scanned object and derive one or more descriptions of the scanned object, e.g., “image of St.-Mark-Square-Venice”. Thus, a second type of attribute may describe the content obtained by software logic that may be triggered by the event, e.g.,

EventType=“scan”

EventContent=“St-Mark-Square-Venice”

Yet another type of attribute that may be used in a query as an applicability constraint is a user attribute, which specifies a characteristic of the mobile device user. Examples of user attributes include gender and age.

Thus, at a given moment, the statement “John takes a picture using app X running on his mobile device 123 at location L, Date D, at time T” describes a state of the mobile device that may be captured as follows.

<Device=123, App=X, location=Y, Time=T, Date=D>

The corresponding user and event information may be captured as follows.

<user=Male, EventType=Snap, EventContent=“St-Mark-Square-Venice”>

In the above exemplary description, the value of the EventType attribute specifies identifiers describing one or more events, and the value of the EventContent is inferred by software logic that may be incorporated within the app (e.g., by using feature recognition technology), etc.

Thus, as described above, in some embodiments we extend the context of mobile devices to include state, event, event content and/or user attributes. Furthermore, the techniques described above for extracting snippets from web resources may be extended so that the snippet attributes stored in the snippet index may include state, event, event content and/or user attributes. That is, a developer whilst developing a web resource, may include in the web resource information that can be extracted as state, user and/or event and event content attributes. The information may then be utilized by snippet extraction procedures (either by the “push” or “pull” methods as described above) to extract and store snippets in the snippet index. With reference to FIG. 5, this is tantamount to adding additional columns to the table depicted therein, the additional columns corresponding to additional attributes that can serve as applicability constraints.

The above-described method for identifying relevant snippets may now be described as follows.

-   -   1. An application running on mobile device “M” uses the internal         systems of “M” to sense its context (e.g., location, date, time,         state, user and event attributes) encapsulates the context into         a query and sends the query to the snippet system. Not all the         attributes need to be sent or sensed, e.g., only a proper subset         of the attributes may be transmitted.     -   2. The snippet system receives the incoming query.     -   3. The snippet system retrieves those snippets from the snippet         index whose applicability constraint attributes “match” the         context of the incoming query.

It is important to understand the nature of the “match” operation in the method described above. Consider, by way of example, the matching of the location attribute contained in the mobile device's context with the location attribute specified in a snippet. The mobile device's location attribute value may specify a GPS coordinate value or a pair of latitude and longitude values. The snippet's location attribute may specify a value as a geographic region covering, say, “Yankee Stadium”. Thus, the method envisions that any mobile device location falling within the specified region may be a target for matching.

In general, the matching procedure that is employed need not be a “syntactic” equality-based matching. Rather, a semantic and “fuzzy” matching procedure may be used, wherein two attribute values, each provided as a range of values, may be considered to “match” as long the corresponding ranges of values “intersect”. For example, attribute “X=[1, 2, . . . , 10]” may be taken to match attribute “Y=[3,4,5]”, etc. Additionally, one may specify inclusion and exclusion relationships based on sets such as in “X matches a set of values Y if any member of X is contained in Y”, etc. Moreover, every attribute included in the query need not necessarily match one of the attributes in a snippet. In general, the term match may encompass the concept of a “best match” as well as, in some embodiments, the concept of an “exact match.”

Consider the following example. One or more service providers create web resources to display Virtual Reality (VR) objects, such as a holographic or 3-D rendition of a resort and other geographical area. The VR objects may be accessed by users at specific web locations given by resource identifiers, e.g., web addresses. The service providers create one or more snippets containing short descriptions or descriptive phrases of the VR objects, map those descriptions or phrases to the resource identifiers and push the resulting snippets to the snippet index, wherein the snippets are stored.

In another example, a user launches an application on his mobile device and scans a page of a physical book containing an image. This causes the application to recognize an event (EventType=scan). Internal software logic in the application operates and produces a descriptive phrase for the scanned object, namely EventContent=St-Mark-Square-Venice. As described above, the state and event attributes are packaged by the app and sent to the snippet system as a query.

The snippet system receives the query and during the above-described matching process finds one or more snippets that contain phrases matching “St-Mark-Square-Venice” (among other matching attribute values). The snippets so identified may be sent in a response to the user, whereupon the user may click one or more returned snippets to cause execution of the snippets. During execution a snippet may resolve the descriptive phrases within the Event Content attributes, if any, to the corresponding resource locations, e.g., St-Mark-Square-Venice may be resolved to the address of a specific web resource that may be present such as, for instance, a virtual reality rendition of St Mark Square.

Thus, the user while reading a physical book may benefit from seeing a virtual reality rendition of an especially constructed object relating to the contents of the book. The rendition may occur on the device being used by the user to scan the page or in a holographic display, etc.

Furthermore, in some embodiments the app may request the user to undertake a series of actions in order to obtain web content about items discussed in the book. For instance, the app may request that the user performs an action to identify the book, e.g., “Scan the title and ISBN number of the book.” The App may then parse the scanned information, possibly using Optical Character Recognition technology, to construct the EventType and EventContent attributes and their corresponding values using its internal software logic. Thus, the app may construct a phrase (e.g., “Romeo-and-Juliet-Shakespeare”) that is used as the EventContent attribute.

One way that an application may recognize specific events is by using software logic to define a table that lists events as actions taken by the software logic. FIG. 7 shows one example of such a tabular structure. The first column lists the EventType and the second column lists the associated values of the EventType. The third and fourth columns show examples of various kinds of EventContent attributes and their corresponding values.

As previously mentioned, event attributes may also arise from actions performed by devices associated with and proximate to a mobile device. For example, a smart watch may be proximate to and associated with a mobile device. Information about the wearer's heart rate may be obtained from such a smart watch. When such data is received by an application running on the mobile device, it may be recognized as a certain EventType (=heartRate) and internal software logic may analyze the received information to obtain, say EventContent=highHeartRate. The query to the snippet index system may then find snippets that are relevant to the indicated EventContent based on attribute matching criteria as described above. Furthermore, a range of heartRate values may be used in the matching.

Another example of an event arises when an application receives information indicating that a user has walked more than a certain number of steps, e.g., using a mobile device's pedometer. In this case, a descriptive phrase such as “strenuous walking” may be assigned as the value of the EventContent attribute and may thus lead to finding snippets that relate to such a condition.

Another method of recognizing events uses software logic to instruct the user to cause an action to be performed, which action gives rise to event and event content attributes. For example, software logic of an application may engage a mobile device user in a series of dialogs, prompting the user to scan specific pages in a certain sequence, or to scan a particular page (e.g., scan title page of the book), etc.

As stated earlier, a query may also contain user attributes. Thus, relevant snippets may be returned by the snippet system that corresponds to the preferences of the user, i.e., the snippets that are returned may be personalized to the user of the mobile device. Thus, two distinct users may be provided with different sets of relevant snippets.

FIG. 8 provides an illustrative example of the above process. A specific page of a physical book 100 is scanned using an application on the user's mobile device 200. The application is specially configured to recognize certain events, scanning being one such event. The application prepares a query that includes the state, user and event attributes and transmits the query to the snippet processing system 300 that, in turn, responds with the relevant snippets. The relevant snippets may be returned to the originating device 200 or to another specified device, referred to as an associated device 400. The alternative device that is specified may be designated by programmatic considerations or by pre-defined or run-time provisioning rules.

In summary, the context of a mobile device may contain calendar, geographic, state, event, user and/or a variety of other attributes as determined, for example, by an application running on the mobile device. Additionally, the calendar attribute may specify the current time and place where the mobile device is located or a hypothetical location and place where the mobile device may be at a specified time in the future. Attributes describing the context are packaged into a query and transmitted to the snippet system for processing.

We now examine a further extension of the notion of a context of a mobile device. In the specification as described so far, the attributes location, time, date and state attributes, etc., of a given mobile device comprise its context. Furthermore, the location, date and time may specify places and times/dates in the future.

When the context of a mobile device is received by the snippet index (encapsulated as a query), the snippet index returns the matching snippets as a response to the query, where the matching snippets have attribute values that match the attribute values in the context of the mobile device. Such a messaging method was described above as “Matching Method 2”.

As an extension of the above ideas, we allow a mobile device to transmit one or more mobile contexts, i.e., a plurality of mobile contexts, to the snippet system (in the form a query). As an example, the collection may have the form depicted as follows.

[context1(loc, time, day, device, event, . . . ,), context2(loc, time, day, event,), . . . ]

The following method describes the matching process using a collection of contexts.

-   -   1. [Matching Method 3] An application running on mobile device         “M” receives a collection of contexts (each specifying e.g.,         location, date, time, state, user and event attributes),         encapsulates the collection as a query and sends the query to         the snippet system. Not all the attributes may be sent or         sensed, e.g., only a proper subset of the attributes may be         transmitted.     -   2. The snippet system receives the incoming query.     -   3. The snippet system retrieves those snippets from the snippet         index whose applicability constraint attributes “match” the         contexts of the incoming query.

As an alternative embodiment of step (1) above, the collection of mobile device contexts may be encapsulated as one or more queries and transmitted to the snippet system in turn.

Consider the following two examples in which two or more contexts are employed.

A user of a routing application running on a mobile device uses the application to find a route between a starting and ending geographic location along with starting times and dates, e.g., from his house to a destination. The routing application constructs the desired route and offers an option to the user to display available snippets. If the user agrees, the application decomposes the constructed route into a sequence of points in a three-dimensional coordinate system, by way of example, [(l1,t1,d1), (l2,t2,d2), . . . ]. It is to be noted that such decomposition is similar in form to a collection of mobile device context attributes. Thus, the decomposition may be converted into a collection of (mobile device) contexts. Further, the decomposition may be limited to a pre-determined number of “points” along the route.

The routing application then converts the decomposed triplets into a collection of mobile device contexts, encapsulates them into one or more queries and invokes the snippet index system with the one or more queries.

It should be noted that in order to facilitate the use of the snippet index system described herein by various applications such as the routing application discussed in this example, the snippet system might publicize an Application Programming Interface (API) that may be used to construct queries in an acceptable format.

Continuing the above example, the snippet system receives the one or more queries and, in response, returns a collection of matching snippets. To display the returned snippets, in one embodiment the invoking application may depict the proposed route R as a visual object (i.e., a map) with superimposed snippets along the route R, much like signposts. Thus, the application constructs an augmented reality object depicting the map of the route adorned with snippet information.

As a second example, consider a user using a camera application on his mobile device to view his surroundings through the range finder of the camera on his mobile device. The camera application detects the use of the camera resource and the action of loading an image in the range finder. As described above, the loading may be detected by the application as an event (eventType=load-image) and the application may analyze the image to generate a corresponding description that can be used for the Event Content attribute, e.g., eventContent=Main-St-Montclair.

Alternatively, the user may use a gesture to indicate to the camera application that his action may be interpreted as a command or an event to be processed by the application.

The camera application proceeds to get the location of “Main-St-Montclair” from one of many available web resources, e.g., using an API provided by web-based mapping services.

Furthermore, the camera application utilizes its internal device resources to get the time and date of the action being performed. It is thus in a position to construct a collection of mobile device contexts as described above, and to encapsulate the collection into a query that it may transmit as a query to the snippet system.

Upon receiving the response from the snippet system, the application may decide to display the returned snippets, for instance, as balloons augmenting the image of Montclair's Main Street, i.e., an augmented reality view of the Main Street adorned with snippet information.

A recent trend in computing circles is to associate (or attach) many different kinds of resources to one or more, private or public, block chain environments. For example, documents containing sensitive information may be “attached” to a block chain so that access to the documents is controlled (e.g., via cryptographic keys), is verifiable (e.g., via logs maintained by block chains), and the identities of user's that access a document are known. Other examples of resources being attached to block chains are smart devices, web pages and web sites, software applications, data sheets, databases, spreadsheets, etc.

A block chain environment may be viewed as a marketplace where different entities may be associated with each other via different sets of agreements (also called contracts). Thus, for example, a smart device may have a contract with a billing provider who bills users of the smart device. Both the smart device and billing service developers benefit from such an association. The block chain controls the access to the resources, maintains logs of usage, etc.

Another kind of resource that may benefit from block chain environments is that of applications. The current association between apps and app stores is rigid and inflexible and could be disrupted and made completely flexible if apps were to be associated with block chain environments.

Thus, there is a need to allow owners of resources to choose from a wide variety of service providers through a flexible set of agreements.

One way in which resources may be attached to block chains is by treating the block chain as a web resource that contains multiple sub-objects (resources) attached to it (the block chain). Thus, the block chains become a web resource. In that case, the methods and systems of the present invention allow the block chain and the resources attached to it to be represented by snippets in the snippet index, said snippets acquired by either a pull method or a push method, as described earlier.

Another way in which resources may get attached to block chains is to define a new address space and attaching one block chain to one address in the address space. Thus, the new address space becomes a structure that is independent of the web. Again, block chains and their sub-objects in such an address space may be represented by snippets.

Yet another method by which resources may get attached to block chains is by associating an IP address with a block chain. In such a case, one IP address may represent both the address of a website and a block chain, as if two entities reside at the same address.

Thus, resources attached to block chains may be represented by snippets in a snippet system and be subjected to search mechanisms as described below.

The present invention envisages, as one preferred embodiment, that a multitude of resources and service providers may be attached to one or more private and/or public block chains. Block chains may thus be thought of as (virtual) marketplaces. As a consequence, there is a commercial need to provide users to search one or more block chains for resources attached therein.

The system and methods presented in the present invention facilitate the above embodiment. In particular, the resources attached to a block chain may be “crawled” by the snippet system or the resources themselves may “push” snippets to the snippet system as described above. The snippets thus acquired contain attributes identifying the block chain environments. Employing the methods described above, we may search the snippet index for resources attached to a block chain. Therefore, the snippet system described herein may be viewed as a search engine for finding resources attached to one or more block chains, private or public, much like conventional web search engines allow websites to be found by using conventional search engines.

More particularly, the methods of searching a snippet index may now be extended as follows. In the presentation described above, one or more applications on a mobile device capture the device's mobile context, encapsulate it as a query and transmit the query to the snippet processing system. That is, snippets are deemed to be associated with resources in a geographical environment usually specified via location, time and day, state of the device and application event attributes.

We extend this formalism by allowing the resources to be associated with block chain environments.

Thus, generally speaking, a query from a mobile device to the snippet system may be thought of as interrogating the snippet system for snippets that are relevant to the one of more contexts of the mobile device in a geographic environment or a block chain environment.

To summarize, resources may be attached to geographical environments and/or to block chain environments. Such resources may be searched by use of the snippet system and methods described herein.

Illustrative Operating Environment

Aspects of the subject matter described herein may be described in the general context of computer-executable instructions, such as program modules, being executed by a computer. Generally, program modules include routines, programs, objects, components, data structures, and so forth, which perform particular tasks or implement particular abstract data types. Aspects of the subject matter described herein may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in both local and remote computer storage media including memory storage devices.

Also, it is noted that some embodiments have been described as a process which is depicted as a flow diagram or block diagram. Although each may describe the operations as a sequential process, many of the operations can be performed in parallel or concurrently. In addition, the order of the operations may be rearranged. A process may have additional steps not included in the figure.

The claimed subject matter may be implemented as a method, apparatus, or article of manufacture using standard programming and/or engineering techniques to produce software, firmware, hardware, or any combination thereof to control a computer to implement the disclosed subject matter. For instance, the claimed subject matter may be implemented as a computer-readable storage medium embedded with a computer executable program, which encompasses a computer program accessible from any computer-readable storage device or storage media. For example, computer readable storage media can include but are not limited to magnetic storage devices (e.g., hard disk, floppy disk, magnetic strips . . . ), optical disks (e.g., compact disk (CD), digital versatile disk (DVD) . . . ), smart cards, and flash memory devices (e.g., card, stick, key drive . . . ). However, computer readable storage media do not include transitory forms of storage such as propagating signals, for example. Of course, those skilled in the art will recognize many modifications may be made to this configuration without departing from the scope or spirit of the claimed subject matter.

Moreover, as used in this application, the terms “component,” “module,” “engine,” “system,” “apparatus,” “interface,” or the like are generally intended to refer to a computer-related entity, either hardware, a combination of hardware and software, software, or software in execution. For example, a component may be, but is not limited to being, a process running on a processor, a processor, an object, an executable, a thread of execution, a program, and/or a computer. By way of illustration, both an application running on a controller and the controller can be a component. One or more components may reside within a process and/or thread of execution and a component may be localized on one computer and/or distributed between two or more computers.

The foregoing described embodiments depict different components contained within, or connected with, different other components. It is to be understood that such depicted architectures are merely exemplary, and that in fact many other architectures can be implemented which achieve the same functionality. In a conceptual sense, any arrangement of components to achieve the same functionality is effectively “associated” such that the desired functionality is achieved. Hence, any two components herein combined to achieve a particular functionality can be seen as “associated with” each other such that the desired functionality is achieved, irrespective of architectures or intermediary components. Likewise, any two components so associated can also be viewed as being “operably connected”, or “operably coupled”, to each other to achieve the desired functionality. 

What is claimed is:
 1. A method of providing relevant information to a mobile device over a wireless communication link, comprising: comparing a context of the mobile device to calendar attributes and/or geographic attributes of stored snippets stored in a searchable index, the context of the mobile device including a current location of the mobile device or a location where the mobile device is located on a specified date, the searchable index including a searchable data structure that stores the stored snippets, each of the stored snippets being extracted from a web resource, each of the snippets including one or more searchable attributes of the web resource with which the respective snippet is respectively associated, the calendar attribute of a snippet specifying when additional information in the snippet is applicable and the geographic attribute of a snippet specifying where the additional information in the snippet is applicable; identifying snippets stored in the searchable data structure based at least in part on a match between the context of the mobile device and the calendar attributes and/or the geographic attributes of the stored snippets; and causing at least some of the identified snippets to be delivered to the mobile device or a display device associated with the mobile device.
 2. The method of claim 1, further comprising pushing one or more of the identified snippets to the mobile device.
 3. The method of claim 1, wherein the searching, identifying and delivering is performed in response to a search request received from the mobile device.
 4. The method of claim 3, wherein the search request is received from programmatic logic without user intervention.
 5. The method of claim 1, wherein the searchable index includes an association between each of the snippets and the respective web resource from which the respective snippet it is extracted.
 6. The method of claim 5, wherein delivering at least some of the identified snippets includes assembling the identified snippets into a snippet page that is displayable on the mobile device.
 7. The method of claim 6, further comprising ranking the identified snippets, wherein delivering the identified snippets includes presenting the identified snippets in rank order.
 8. The method of claim 7, wherein the identified snippets are ranked based at least in part on predicting which of the identified snippets is most useful to a user of the mobile device.
 9. The method of claim 8, wherein predicting which of the identified snippets is most useful is based at least in part on online trending information.
 10. The method of claim 1, wherein the calendar and geographic attributes respectively specify when and where an application and/or service is available for use from the respective web resource from which the snippet was extracted, the snippets being applicable to the mobile device when the application and/or services respectively specified by the snippets are available when and where the mobile device is located.
 11. The method of claim 1, wherein the identified snippets delivered to the mobile device are only identified snippets that are associated with services or applications that are available for use by the mobile device at the current location or the location where the mobile device is located on the specified date.
 12. A method of providing relevant information to a mobile device over a wireless communication link, comprising: comparing a context of the mobile device to searchable attributes of stored snippets stored in a searchable index, the context of the mobile device including a plurality of attributes of the mobile device, the searchable index including a searchable data structure that stores the stored snippets, each of the stored snippets being extracted from a web resource, the searchable attributes of each stored snippet being obtained from the web resource from which the stored snippet is respectively extracted; identifying snippets stored in the searchable data structure based at least in part on a match between the context of the mobile device and the searchable attributes of the stored snippets; and causing at least some of the identified snippets to be delivered to the mobile device or a display device associated with the mobile device.
 13. The method of claim 12, wherein the plurality of attributes of the mobile device includes at least one state attribute defining at least one state of the mobile device.
 14. The method of claim 13, wherein the at least one state attribute includes an identity of a mobile device type.
 15. The method of claim 13, wherein the at least one state attribute includes an identifier of an operating system of the mobile device.
 16. The method of claim 15, wherein the at least one state attribute includes information obtained from one or more sensors incorporated in or associated with the mobile device.
 17. The method of claim 13, wherein the at least one state attribute includes an identifier of an application hosted on the mobile device.
 18. The method of claim 13, wherein the plurality of attributes includes at least one event attribute and at least one event content attribute associated with the event attribute, the at least one event attribute specifying an action performed by the mobile device and the event content attribute associated therewith includes content obtained as a result of the action being performed by the mobile device.
 19. The method of claim 18, wherein the action includes performing a measurement using a sensor incorporated in or associated with the mobile device.
 20. The method of claim 19, wherein the measurement is selected from the group consisting of obtaining an image or video, measuring one or more health related parameters of a user of the mobile device, measuring motion of the mobile device and measuring ambient temperature. 